Content creation and distribution system

ABSTRACT

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for receiving and distributing user-generated video content. In one aspect, a method includes receiving video data from a client computing device, where the video data is captured using a camera connected to the client computing device in accordance with instructions executed on the client computing device to provide the video data in accordance with predetermined constraints. The video data is automatically transcoded into at least one different format based on user credentials associated with a user of the client computing device and/or attributes associated with the video data. At least one format of the transcoded video data defines a video file in a format appropriate for inclusion in a linear television programming transmission. The transcoded video data is uploaded to a server for distribution.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of, and claims priority to, U.S.patent application Ser. No. 13/185,471, entitled “Content Creation andDistribution System,” to in inventors Mark Harwell, Christopher W.Wyatt, and Ryland Reed, which was filed on Jul. 18, 2011. Thisapplication is also a continuation-in-part application of, and claimspriority to, U.S. patent application Ser. No. 13/013,775, entitled“User-Generated Social Television Content,” to inventors Christopher W.Wyatt, Mark Harwell, and Ryland Reed, which was filed on Jan. 25, 2011.These disclosures of the foregoing applications are incorporated hereinby reference in their entirety.

BACKGROUND

It has become relatively easy for individuals and groups of individualsto take digital photographs and to record video, and to distribute thiscontent to others over the Internet or other data networks. Such contentis referred to as being “user generated” content. Still and videocameras, which are now common features on mobile phones, can be used totake photographs and to record videos that are immediately available forsharing with others through a multi-media messaging service or email,video file sharing sites, social network and similar services on theInternet that publish (to selected individuals or groups, or toeveryone) or otherwise make available the photographs and video over theInternet. Some dedicated cameras and storage cards now have wireless ornetwork connectivity and video can be uploaded to remote servers forsharing. Individuals or “consumers” distribute their photos and videosby uploading them to web-based services that publish them for friends,family, social or business contacts or anyone with access to theInternet to view. When user-generated content is uploaded or shared fora specific purpose, such as for example, in response to a widelydisseminated request for a certain type of content, it may be referredto as crowd-sourced content.

Most consumer equipment capable of capturing photos or video is now ableto do so in high definition. Inexpensive computer application programsallow individuals to edit photographs, videos and other graphics into asingle work with nearly professional results, and to render theresulting work or “content” in standard formats for playback on a widerange of devices. Services for sharing user-generated video,photographs, and music abound on the Internet. For example, a number ofvideo sharing sites allow people to upload, encode and share videos onthe web.

On the other hand, most people still view professionally producedtelevision programs (“programs”) and motion pictures (“movies”) usingtraditional television services. Programs are typically distributed totraditional television service providers by so-called “televisionnetworks,” who possess the legal rights necessary to distribute theprograms, and who are sometimes also involved in producing theprogramming. Those who provide transmission services for television, andprovide television service to viewers, are referred to as “carriers” orMulti-Service Operators (“MSO”). Most television networks “sell” shortperiods of time during the programming for transmission of advertising,known as “commercials,” “advertisements,” “ads” or “ad spots,” thatpromote businesses or programming on the network. These time slots canalso be used for transmission of public service announcements. Thesetime slots may also be used for any other promotional purposes.

Television transmission or distribution systems used by traditionalcarriers of television programming include terrestrial broadcaststations, satellite television, and cable television systems, as well astelecom delivery network services such as VDSL and FiOS offered overbroadcast telecommunication or data networks, whose operators providetelevision services similar to what are offered by cable and satellitetelevision service providers. However, standards have been formulated,or are in the process of being formulated, for using Internet protocolsand the public Internet to distribute television programming using“live” IP-multicast or IP unicast streams that can be received by anyonewith any type of broadband data connection to the Internet.

Though some television programs are available over the Internet andtraditional carriers on an on-demand basis, traditional televisionprogramming for a television network is linear, meaning that programs—anepisode of a television series, a news program, or a movie, forexample—are scheduled so that they are transmitted sequentially,according to a predefined schedule, to carriers for transmission overtheir systems for substantially contemporaneous receipt by theirsubscribers or, in the case of terrestrial broadcast stations, by thosewho receive their broadcast signal. In linear programming, the programsto be transmitted to the audience, and the schedule for transmitting ofthe programs, are usually planned in advance of the time of transmissionto an audience. The programming schedule, usually expressed in the formof a programming grid, specifies what program and, if applicable,episode is to be transmitted on each day and at any given time duringthe periods in which the network is scheduled to transmit. Televisionprograms can include, but are not limited to, television series, motionpictures, news programs, reality television programs, sporting events,and other audio/visual works. The programs are often pre-recorded.However, programs can be “live.” Generally, such programs areprofessionally produced. The network either owns or licenses the legalrights to distribute them.

Traditional linear programming is commonly divided into thirty-minute orhour-long programming segments, though it can be divided into shorter orlonger segments, depending on network preferences. Programs can occupymore than one segment. Within a typical thirty-minute program segment,for example, between twenty-two and twenty-six minutes are reserved fortransmitting the program. The remaining time is divided among 2-5segments for commercials and/or other promotional announcements. Thosesegments are typically subdivided into multiple time slots for sale toadvertisers. The duration of the advertising segments and each of thetime slots can be chosen to be any desired length. The networktransmits, or arranges for transmission of, its signal so that thehalf-hour segments begin at the top and bottom of each hour. However,networks can, and do sometimes, adjust the start and end time ofprograms. A network may or may not transmit more than one signal, or“feed,” to account for time zone differences or other considerations.

SUMMARY

Implementations of the present disclosure are generally directed to avideo file content creation and distribution system (e.g., for thecreation and distribution of user-generated and/or crowd-sourced videocontent). The system can include a content creation sub-system thatprovides users with a video file recording and editing system thatprovides an easy-to-use interface, does not require the users to haveknowledge of video formatting or computer file systems, andautomatically uploads video files or other content to a server. Thevideo file recording and editing system can use a web server-based thinclient application capable of displaying a user interface through abrowser on a user device or a specialized application capable of runningon a user device (e.g., on a mobile device or a tablet computer). Ineither case, the application can interface with user device's nativerecording capabilities to capture either high definition (“HD”) formator standard definition (“SD”) format video files. The video filerecording and editing system guides the user through a video filecreation and submission process that captures video via a video cameraeither built-in, or connected to, the user device to create a video filethat meets requirements for submission to a content distributionsub-system, and submits the video file to the content distributionsub-system.

The content creation sub-system can facilitate convenient creation andseamless uploading of crowd-sourced video files (e.g., audio-visualcontent created in response to a broadcasted request for videos relatingto a particular topic) or other user-generated content (e.g., videofiles generated by a user along with some form of payment for inclusionin a television broadcast). For example, the video file recording andediting system can ensure that the submitted video files satisfy certainparameters so that the files have a quality level appropriate forinclusion in linear television programming and so that the files can beautomatically and conveniently transcoded into one or more video fileformats (in accordance with relevant frame rates, bit rates, etc., whichmay be dependent on the intended destination of the content) accordingto the intended destination. The video files can be submitted through aparticular web page and/or assigned a particular identifier indicatingthe type of submission (e.g., indicating that the video file issubmitted in response to a specific request for video submissions, orindicating that the video file is intended for inclusion in an availablelinear programming segment of a specific program, or is meant to be seenonly on the Internet as part of a video blog or other Internetexperience).

The content distribution sub-system includes an administratorapplication capable of running on a computer (e.g., a server). Thecontent distribution sub-system can perform electronic filtering ofvideo files and can automatically transcode the video files into anappropriate format based upon destination (e.g., one format if the videocontent is intended for distribution via linear television programmingand another format if intended for distribution on an Internet videoblog). Based upon rights and/or administrative privileges, theadministrator application allows a television or other productionprofessional or Internet web site administrator to review user-generatedor crowd-sourced video files through a web-based, server-based, or localvideo administration tool through which the producer or administratorcan authorize certain video files for automatic inclusion in lineartelevision programming over traditional or IP-based televisiondistribution platforms. The content-distribution sub-system may also beused for production of content to be released in theaters (e.g., movies)and/or to send selected files to an editing system for more specificediting purposes. The video files can be organized according to dataincluded in a uniform resource locator (URL) or other identifierindicating the type of submission. Accordingly, a producer oradministrator can be presented with a set of videos that relate to acommon topic or that are intended for possible inclusion within aparticular linear television programming segment. The producer oradministrator may also use filtering tools to determine which videofiles to review or which video files should be selected for inclusion inthe linear programming. Once selected, video files are directed to anappropriate server for distribution to an appropriate destination (e.g.,television or Internet).

In general, innovative aspects of the subject matter described in thisdisclosure may be embodied in methods that include the actions ofreceiving video data from a client computing device, automaticallytranscoding the video data, and uploading the transcoded video data to aserver for distribution. The video data is captured using a cameraconnected to the client computing device in accordance with instructionsexecuted on the client computing device to provide the video data inaccordance with predetermined constraints. The video data isautomatically transcoded using a server into at least one differentformat based on user credentials associated with a user of the clientcomputing device and/or attributes associated with the video data. Atleast one format of the transcoded video data defines a video file in aformat appropriate for inclusion in a linear television programmingtransmission. Other embodiments of this aspect include correspondingsystems, apparatus, and computer programs, configured to perform theactions of the methods, encoded on computer storage devices.

These and other embodiments can each optionally include one or more ofthe following features. The instructions executed on the clientcomputing device include scripts received by the client computing devicefrom a web application. The instructions executed on the clientcomputing device are executed within at least one of a browser or abrowser plugin on the client computing device. The instructions executedon the client computing device are included in an application installedon the client computing device. At least a portion of the video data isbuffered on the client computing device using scripts included in theinstructions executed on the client computing device based on bandwidthconstraints for transmitting the video data from the client computingdevice. The video data is transmitted by the client computing device inFLV format. The video data is transmitted by the client computing devicein a native media container format for the client computing device. Thepredetermined constraints include a bit rate and an image resolutionsufficient to enable transcoding of the video data into the formatappropriate for inclusion in the linear television programmingtransmission. Transcoding the video data includes using a predeterminedautomated transcoding workflow corresponding to the predeterminedconstraints to transcode the video data into the transcoded video data.Transcoding the video data includes transcoding the video data into aplurality of different video file formats. An automated review of thevideo data and/or the transcoded video data is performed to identifypotentially inappropriate content. The transcoded video data isretrieved for manual review, and a review interface is presented wherethe review interface is adapted to provide an indication of at least oneframe within the transcoded video file including content identified aspotentially inappropriate content and allow an administrator to selectthe transcoded video file for manual review. The transcoded video datais retrieved for manual review, a review interface adapted to allow anadministrator to select among a plurality of transcoded video files formanual review is presented, a selection of a particular transcoded videofile for review is received through the review interface, video definedby the particular transcoded video file is presented through the reviewinterface in response to the selection, and a selection of theparticular transcoded video file for publication is received through thereview interface. Uploading the transcoded video data to a server isperformed in response to the selection of the particular transcodedvideo file for publication. The video data is received in response to arequest to submit content for potential inclusion in a linear televisionprogramming transmission. Automatically transcoding the video dataincludes transcoding the video data into at least one format appropriatefor Internet distribution, and the transcoded video data is stored inthe at least one format appropriate for Internet distribution on a webserver adapted to allow retrieval through a web page. The transcodedvideo data is distributed to a plurality of social networking web sites.The transcoded video data is distributed in a video blog.

Other aspects of the subject matter described in this disclosure may beembodied in methods that include the actions of displaying, on a clientcomputing device, a user interface adapted to allow a user toselectively record content including high definition video contentthrough a digital camera communicably coupled to the client computingdevice, receiving a user selection to record content, and capturing highdefinition video data using the digital camera during a continuousrecording segment. The high definition video data is formatted inaccordance with predetermined constraints, and at least a portion of theformatted high definition video data is transmitted to a storage serverduring the continuous recording segment. Other embodiments of thisaspect include corresponding systems, apparatus, and computer programs,configured to perform the actions of the methods, encoded on computerstorage devices.

These and other embodiments can each optionally include one or more ofthe following features. Formatting the high definition video dataincludes formatting the high definition video data in FLV format. Theoperations are performed using scripts transmitted to the clientcomputing device in a web page and executed on the client device usingat least one of a web browser or a web browser plugin. The predeterminedconstraints are adapted to enable a transcoding server to performautomated transcoding of the high definition video data into a pluralityof video file formats. A portion of the high definition video data iscached on the client computing device for transmission in accordancewith bandwidth limitations on transmitting the formatted high definitionvideo data. One or more attributes are associated with the formattedhigh definition video data, where the one or more attributes areassociated with a request for submissions of content to be included in atelevision broadcast and/or a user credential.

Other aspects of the subject matter described in this disclosure may beembodied in methods that include the actions of displaying, on a clientcomputing device, a user interface adapted to allow a user toselectively record content including high definition video contentthrough a digital camera communicably coupled to the client computingdevice, receiving a user selection to record content, and capturing highdefinition video data using the digital camera during a continuousrecording segment. The high definition video data is formatted inaccordance with predetermined constraints. A connection is establishedwith a content submission server in response to a user selection toupload the high definition video data, and the formatted high definitionvideo data is transmitted to a storage server using the connection inresponse to the user selection. The predetermined constraints areadapted to facilitate transcoding of the formatted high definition videodata into a format appropriate for inclusion in a linear televisionprogramming transmission. Other embodiments of this aspect includecorresponding systems, apparatus, and computer programs, configured toperform the actions of the methods, encoded on computer storage devices.

These and other embodiments can each optionally include one or more ofthe following features. Formatting the high definition video dataincludes formatting the high definition video data in a native mediacontainer format for the client computing device. The operations areperformed using instructions transmitted to the client computing devicedownloaded from a web server and installed on the client device, andcapturing high definition video data using the digital camera includesinterfacing with native device recording capabilities. The predeterminedconstraints are adapted to enable a transcoding server to performautomated transcoding of the high definition video data into a pluralityof video file formats. One or more attributes are associated with theformatted high definition video data, and the one or more attributes areassociated with a request for submissions of content to be included in atelevision broadcast and/or a user credential. A connection isestablished with a web server to retrieve at least one attributeassociated with a request for submissions of content.

Other aspects of the subject matter described in this disclosure may beembodied in systems that include a user device and one or more serversoperable to interact with the user device. The one or more servers arefurther operable to receive video data in a predetermined format fromthe user device, transcode the video data into one or more video formatsthat differ from the predetermined format using an automated transcodingworkflow corresponding to the predetermined format, store the transcodedvideo data, and distribute the transcoded video data for inclusion in atelevision transmission. Other embodiments of this aspect includecorresponding methods, apparatus, and computer programs, configured toperform the actions of the methods, encoded on computer storage devices.

These and other embodiments can each optionally include one or more ofthe following features. The one or more servers are further adapted toprovide instructions for execution on the user device in a web page,wherein the instructions are adapted to cause the user device to capturethe video data using a camera connected to the user device and totransmit at least a portion of the video data to a web server of the oneor more servers as the video data is captured. The one or more serversare further adapted to transcode the video data into a formatappropriate for inclusion in a linear television programmingtransmission. The one or more servers are further adapted to transcodethe video data into a format appropriate for Internet distribution. Theone or more servers are further adapted to transcode the video data intoa plurality of different formats. The one or more servers are furtheradapted to perform an automated review of at least one of the video dataor the transcoded video data to identify potentially inappropriatecontent. The one or more servers are further adapted to retrieve thetranscoded video data for manual review and present a review interfaceadapted to provide an indication of at least one frame within thetranscoded video file including content identified as potentiallyinappropriate content, and allow an administrator to select thetranscoded video file for manual review. The one or more servers arefurther adapted to retrieve the transcoded video data for manual review,present a review interface adapted to allow an administrator to selectamong a plurality of transcoded video files for manual review, receive aselection of a particular transcoded video file for review through thereview interface, present video defined by the particular transcodedvideo file through the review interface in response to the selection,and receive a selection of the particular transcoded video file forinclusion in the television broadcast. The transcoded video data isdistributed for inclusion in a television broadcast in response to theselection of the particular transcoded video file for inclusion in thetelevision broadcast. The one or more video formats are selected basedon at least one of user credentials associated with a user of the userdevice or attributes associated with the video data.

Particular embodiments of the subject matter described in thisspecification can be implemented so as to realize one or more of thefollowing advantages. The subject matter can be used to encouragesubmission of, and facilitate curation of, crowd-source video or otheruser-generated content. The content creation sub-system can be used toensure that video files are received in one or more preselected formatsand in accordance with predetermined parameters, which can facilitateautomated transcoding according to one or more software-implementedtranscoding workflows. Video can be quickly and conveniently transcodedinto one or more formats appropriate for selected types of distribution(e.g., linear television programming or Internet distribution). Receivedvideo can be transcoded for virtually immediate distribution andbroadcast. Video can be automatically filtered to identify potentiallyinappropriate material (e.g., body parts, language, copyrightedmaterial) for exclusion or manual review by an administrator. Thesubject matter can be used to encourage crowd-sourced video submissionand to provide an interactive production process and can eliminateconfusion, time, and expense associated with sourcing and copyingcrowd-sourced or user generated content that can potentially begenerated in multiple formats, frame rates, and bit rates by, amongother things, automatically transcoding video content into a particularformat that is ready for distribution through television in addition toautomatically transcoding the video content into other formats that canbe used for other content distribution outlets. These techniques canreduce cost at the production stage and can provide a production teamwith more time for creative aspects of a production process to produce amore compelling broadcasting product. Videos can be segmented based onuser credentials and/or attributes associated with the content (e.g.,identifying a program for which the content is being submitted).

The details of one or more embodiments of the subject matter describedin this specification are set forth in the accompanying drawings and thedescription below. Other features, aspects, and advantages of thesubject matter will become apparent from the description, the drawings,and the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a functional block diagram of the content creation anddistribution system.

FIG. 2 illustrates a block diagram of basic components of arepresentative example of a content creation and distribution systemarchitecture

FIG. 3 is an example of a web-based recording and uploading userinterface.

FIG. 4 is an illustration of a video source selection control of theweb-based recording and uploading user interface of FIG. 3.

FIG. 5 is an illustration of an audio source selection control of theweb-based recording and uploading user interface of FIG. 3.

FIG. 6 is an illustration of an Internet speed selection control of theweb-based recording and uploading user interface of FIG. 3.

FIG. 7 is an illustration of a duration setting selection control of theweb-based recording and uploading user interface of FIG. 3.

FIG. 8 is an illustration of a famespot timer display of the web-basedrecording and uploading user interface of FIG. 3.

FIG. 9 is an illustration of a peoplemercial timer display of theweb-based recording and uploading user interface of FIG. 3.

FIG. 10 is another illustration of a famespot timer display of theweb-based recording and uploading user interface of FIG. 3.

FIG. 11 is an illustration of a video type selection control of theweb-based recording and uploading user interface of FIG. 3.

FIG. 12 is an illustration of an HD camera availability confirmationcontrol of the web-based recording and uploading user interface of FIG.3.

FIG. 13 is an illustration of a video recording filters control of theweb-based recording and uploading user interface of FIG. 3.

FIG. 14 is an illustration of a video recording controls of theweb-based recording and uploading user interface of FIG. 3.

FIG. 15 is an illustration of a recording countdown display of theweb-based recording and uploading user interface of FIG. 3.

FIG. 16 is a flow diagram representing certain steps of acomputer-implemented process for a system for recording and submittingbroadcast quality digital video from a computer.

FIGS. 17A-C are example screen-shots of an administrative interface forreviewing, authorizing, or declining certain video files.

FIG. 18 is a flow diagram representing certain steps of acomputer-implemented process for a system for recording and submitting“broadcast quality” video files such as famespots, peoplemercials, orvideo blogs from a smart phone, computer tablet, or other mobile device.

FIG. 19 is an example of a mobile recording user interface (MRUI) in anoptions presentation mode of operation.

FIG. 20 is an example of the mobile recording user interface in aduration selection mode of operation.

FIG. 21 is an example of the mobile recording user interface in arecording mode of operation.

FIG. 22 is an example of the mobile recording user interface in aplayback mode of operation.

FIG. 23 is an example of the mobile recording user interface in anuploading mode of operation.

FIG. 24 is an example of the mobile recording user interface in a filenaming mode of operation.

FIG. 25 is an example of the mobile recording user interface in a filesubmitting mode of operation.

FIG. 26 is an example of the mobile recording user interface in anupload success notification mode of operation.

FIG. 27 is a flow diagram representing certain steps of acomputer-implemented process for a system for uploading pre-recordedbroadcast quality digital video from a computer.

FIG. 28 is an example of a video file browsing utility of the web-basedrecording and uploading user interface of FIG. 3.

FIG. 29 is a flow diagram representing certain steps of acomputer-implemented process for a system for uploading pre-recordedbroadcast quality digital video from a mobile device.

FIG. 30 is an example of the mobile recording user interface in theoptions presentation mode of operation.

FIG. 31 is an example of the mobile recording user interface in a videofile browsing mode of operation on the user device's internal video filelibrary.

FIG. 32 is an example of the mobile device in a file playback mode ofoperation.

FIG. 33 is an example of the mobile device in a video file compressionmode of operation after the file is selected for uploading.

FIG. 34 is an example of the mobile device in a video file upload modeof operation.

FIG. 35 is an example of the mobile device in a video file naming modeof operation.

FIG. 36 is an example of the mobile recording user interface in anupload success notification mode of operation.

Like reference numbers and designations in the various drawings indicatelike elements.

DETAILED DESCRIPTION

Implementations of the present disclosure are directed to systems andmethods of creating and distributing crowd-sourced or otheruser-generated video content. Video content is captured on a user deviceand formatted according to predetermined constraints using a webapplication or an installed application. The video content, for example,can be requested for inclusion in a television program. By formattingthe video content according to predetermined constraints, the videocontent can be transcoded into a format appropriate for inclusion in alinear television programming schedule using an automated transcodingworkflow corresponding to the predetermined format to ensure that thetranscoded video file complies with requirements of a particulartelevision broadcaster or television uplink facility. The video can alsobe automatically transcoded into one or more additional formatsappropriate for alternative distribution media (e.g., Internetdistribution or inclusion in a movie production). The video file canundergo an automated review process to check for inappropriate contentand/or to confirm compliance with formatting requirements. The videofile can also undergo a manual review for content marked as potentiallyinappropriate and/or to select among available videos for inclusion in atelevision production. Based on the manual review or through anautomated assignment process, a selected video file can be integratedinto a linear television programming schedule (e.g., by associating thevideo file with a specific slot in the linear programming schedule).Transcoding and review can be performed in accordance with attributesassociated with the video content (e.g., identifying a particulartelevision program that the video content is intended to potentially beincluded in) and/or user credentials for a user that submitted thecontent (e.g., user credentials indicating whether the user isauthorized to submit content for Internet and/or televisiondistribution).

FIG. 1 depicts an example content creation and distribution system(CCDS) 100. The CCDS 100 can be provided as a complex set ofinterconnected software and server systems. These software and systemscan be used to record, transcode, transfer, save, and play-backuser-generated, digital audio/visual content so that various end userscan upload user-captured and/or user-created digital audio/visualcontent from a variety of digital sources for the purpose of airing ordistributing that content through one or more content distributionoutlets. The content can be provided in standard definition (SD) (e.g.,less than 500,000 pixels per frame) or high definition (HD) (e.g.,greater than 500,000 pixels per frame, and typically at least 750,000pixels per frame). The content can be aired or distributed by variousmedia outlets 102, including, for example, on television broadcasts 104,Internet television 106, video blogs 108, video on demand (VOD), withinvarious computer-based social networks, and/or within other online media(e.g., video file sharing services) and applications. In general,content can be in the form of video (with or without accompanyingaudio), can be user-generated or crowd-sourced, and can be representedin files (e.g., video files).

Generally, broadcasts can include the distribution of audio and videocontent to a dispersed audience. Television broadcasts, for example, caninclude the distribution of content using air-wave, satellite, and/orcable technologies. Internet broadcast may also be used and mayfacilitate distribution to a single view or to multiple viewers (e.g.,depending on viewing authorizations and whether the transmission isdistributed on demand or as a one to many broadcast).

In some implementations, CCDS 100 includes a content creation sub-system112 and a content distribution sub-system 116. The content creationsub-system 112 can include a website 110 that is hosted using one ormore computing devices (e.g., server systems), a client application 124that is at least partially executable on a client computing device, anda mobile application 122 that is executable on a mobile computingdevice. The content distribution sub-system 116 can include encoders(e.g., for encoding raw data or other uncompressed video format datainto a compressed video format) and/or transcoders (e.g., fortranscoding one compressed video format into another compressed videoformat) 118, storage servers 114 (e.g., computer-readable memory) and areview and authorization interface 134. Components of the contentcreation sub-system 112 and the content distribution sub-system 116 canbe provided as one or more application programs that can be executedusing one or more computing devices, and/or one or more hardwarecomponents (e.g., computing devices and/or computer-readable memory). Insome implementations, the content creation sub-system is provided as anapplication that is installed on a user computing device 120 to generatedigital content, and/or a back-end computing device, such as a serversystem that communicates with the user computing device 120 to provide athin client application that is executed in part on the server systemand in part on the user computing device 120 (e.g., using a browserapplication on the user computing device 120). In some implementations,the content distribution sub-system 116 can be executed on a usercomputing device 136, and/or a back-end computing device, such as aserver system that communicates with the user computing device 136.

Based upon a user's registration credentials and permissions, which canbe established in part by registration with website 110 of contentcreation sub-system 112, and/or on attributes (e.g., identifying a webpage through which the video is submitted) associated with submittedcontent, the user's content can be automatically distributed to one ormultiple storage locations 114 of content distribution sub-system 116for use and/or for production review. Using encoders 118, digitalcontent provided by the user can be transcoded to an appropriate digitalmedia format for use by destination media outlets 102 (e.g., withintelevision broadcasts 104, Internet broadcasts 106, Internet Video blogs108, and/or other distribution media, including other types of Internetdistribution or for theatrical production, e.g., for presentation in amovie theater). In some implementations, the destination outlets caninclude an online video blog service, as described with reference toFIGS. 7, 8A, and 8B of U.S. patent application Ser. No. 13/013,775.

When the content creation sub-system is implemented as a thin clientapplication or a specialized application installed on a user device, theapplication can enforce predetermined constraints on the captured video.Such constraints can help ensure that the video is in condition to berapidly transcoded for insertion into a linear programming time slot.For example, the application can encode the video and accompanying audiodata at a sufficient bit rate and resolution, among other things, toensure that the video file can be transcoded to produce video ofsufficient quality to be televised and/or to be distributed on theInternet (i.e., in accordance with minimum quality requirements of thetelevision producer or other distributor). By ensuring that thecrowd-sourced video or other user-generated content complies withpredetermined parameters through the application of the content creationsub-system, it is possible to transcode the video or other content andperform a review and/or selection so that the video or other content canbe inserted within the same television show in which the request tosubmit the video or other content is made. Among other things, theapplication can encode the video into a predetermined format to ensurethat the video file is ready for transcoding using a predeterminedtranscoder and predetermined transcoding parameters (or a limited set ofpredetermined transcoders and/or transcoding parameters). In otherwords, the incoming video file can be transcoded using a predeterminedtranscoding process without having to interpret the data, develop atranscoding process, edit the video, and/or perform manual processing.Such techniques allow received video to be quickly transcoded and canfacilitate incorporating captured video into linear programming withinminutes of capture.

The client application (i.e., either thin client application orinstalled application) can also enforce restrictions on the length of avideo that is captured for submission. For example, if a video isgenerated in response to a specific request for video or other contentsubmissions, users may be directed to a particular web page associatedwith the request. By accessing the thin client through that web pageand/or by delivering parameters to a locally installed application onthe user device, a video length restriction can be enforced (i.e., theuser can be prevented from capturing or submitting videos that do notcomply with the length restrictions). In some implementations, thecontent creation sub-system can allow recordings of various durationssuitable for including in time slots of linear programming (e.g., 15seconds, 30 seconds, etc.). For example, an affinity group may not haveits own television program affiliated with its own private-label socialmedia website. In such an instance, members of the affinity group maynot have the option to record a 15-second “famespot” for inclusion inthat affinity group's television program. They may, however, be givenrights to record and submit a 30-second “peoplemercial” that may beviewed on various programs within a television programming lineup. Otherpredetermined lengths may also be used. By enforcing lengthrestrictions, the need to edit the video can be avoided, which can alsoexpedite the process of inserting video into a linear programmingsequence. Users may also be allowed to submit a video file ofunspecified length for inclusion on an Internet video blog or as part ofa linear program, otherwise known as a “social clip.”

Although use of a thin client or specialized application can helpenforce restrictions that can facilitate rapid transcoding and avoidediting, video files that are captured using commercially availablesoftware can also be submitted to the CCDS 100. Such files may bescreened to ensure compliance with any predetermined constraints (e.g.,format and length) that apply to the submission. The constraints mayvary, for example, depending on whether the submission is intended fordistribution through high-definition television programming, throughstandard-definition programming, or through the Internet. Submissionsthat do not comply with the formatting requirements can be rejected foruse with the intended programming and/or stored (e.g., for potentiallyoff-line transcoding and/or for retrieval over the Internet).

To create, edit and upload digital content (e.g., crowd-sourced videofiles), a user can make use of the computing device 120. Examplecomputing devices 120 can include any type of computing device such as adesktop computer, a laptop computer, a handheld computer, a tablet, apersonal digital assistant (PDA), a cellular telephone, a networkappliance, a camera, a smart phone, an enhanced general packet radioservice (EGPRS) mobile phone, or a combination of any two or more ofthese data processing devices or other data processing devices. Thecomputing device 120 can communicate with the CCDS 100 over a network.The network can include a large computer network, such as a local areanetwork (LAN), wide area network (WAN), the Internet, a cellularnetwork, a satellite, or a combination thereof connecting any number ofmobile computing devices, fixed computing devices, and/or serversystems.

As discussed in further detail herein, the creation and editing ofdigital content can be achieved in various manners. For example, thecomputing device 120 can execute a thin client application to provideinput to a server-side computing device over a network. The thin clientapplication can include scripts (e.g., JavaScript, ActionScript) torecord and transmit digital (e.g., video file) content to theserver-side computing device. As another example, an application can bedownloaded to the computing device 120 (e.g., in instances where device120 is a mobile device, tablet computer, or other computing device thatdoes not support scripts or other features necessary to run the thinclient application), which application can be executed to create andgenerate digital content locally at the computing device 120. The nativerecording capabilities of the user computing device 120 can be accessedto receive captured video and audio data through an API on the computingdevice 120. As another example, the computing device 120 can provide aweb interface that enables a user to upload pre-generated video contentto the servers.

The computing device 120, from which a user can create and uploaddigital content, can also impact permissions and distribution of thedigital content. For example, given certain restrictions on wirelessdata networks, submissions from a smart phone or tablet may not beavailable until the user connects to a wireless data access network(LAN, WiFi, 3G, 4G, etc. network) that will allow a more efficaciousupload of the content. As described in greater detail below, mobileapplication software 122 can be downloaded to and executed on thecomputing device 120, which can use the mobile application software 122to record digital video content, for example, in a local file first as amobile video file format, and then transmit the mobile video file fortranscoding and storage on different servers according to the user'sintended final destination for the video content. In someimplementations, as discussed further herein, a client application 124can be downloaded to and executed on the computing device 120 and can beused to record video to local memory 126 and/or to storage locations 114of the distribution sub-system 116. As another alternative, the clientapplication 124 can be implemented as a thin client application, suchthat the recorder functionality can be accessed through a web pageinterface without installing software locally on the computing device120. For example, a user can access a web page through browser softwareon the computing device 120. The web page can provide an interface forcontrolling an HD video capture process using a camera attached to orincorporated into the computing device 120. Scripts within the web pagecan be used to receive audio and video data through APIs on thecomputing device 120 and to format the data into an appropriate formatfor delivery to the content distribution sub-system 116.

In operation, the mobile application 122 software and/or clientapplication 124 software can provide an system that guides the userthrough the recording and submission process with minimal effort orknowledge of formatting, file systems, and uploading on the part of theuser. This system can employ the user interface 130 of the computingdevice 120 to guide the user through a video capture process, using anSD or HD digital video camera 132 on or attached to the computing device120 to obtain a video file suitable for submission to the contentdistribution sub-system 116.

Video files uploaded or recorded from the device 120 to the storagelocations 114 can be reviewed by a reviewing user (e.g., professional)using the review and authorization interface 134 of distributionsub-system 116. The authorization interface 134 enables the reviewinguser to review and authorize video files for inclusion in linearprogramming for distribution by broadcast television and/or Internettelevision and/or other various forms of Internet publication, such asin video blogs or independently on a video file sharing service. Theauthorization interface 134 can also allow the reviewing user to sortand filter submissions according to appropriate factors (e.g., apopularity of the submitting entity or individual; a frequency ofsubmission by the submitting entity or individual; a rating or number ofpoints associated with the submitting entity or individual; title; typeof submission; content label associated with the submission; length ofvideo; whether the video includes any content flagged as questionablematerial; etc.).

In some implementations, the review and authorization interface 134 canbe downloaded to and run on the computing device 136 and can use thecomputing device's memory 138, processor 140, and user interface 142. Insome implementations, the authorization interface 134 can be implementedas an application that is executed using one or more servers, where thecomputing device 136 can execute a thin client application to provideinput to the one or more servers over a network.

The authorization interface 134 can be used to allow a televisionproducer to select crowd-sourced video files for inclusion in live orpre-recorded linear television programming without the need for athird-party editing system. For example, the content creation sub-system112 and/or features built into the content distribution sub-system 116can ensure that received video does not require editing (e.g., bygenerating an initial video file in FLV format or otherwise) and that itincludes an appropriate bit rate and frame rate, and/or can filter outvideo that does not meet predetermined quality parameters, lengthparameters, editorial constraints, or other constraints). Before orduring a television program, the television producer can solicitsubmission from viewers of video on a particular topic. The videos canbe submitted in association with information identifying the televisionprogram for which the video is being submitted (e.g., by submitting thevideo through a particular web page). Videos submitted for a particulartelevision program can be separated from other videos. Submitted videoscan be retrieved simultaneously or sequentially for review and selectionby one or more administrators. For example, the administrators mayselect video for immediate or nearly immediate inclusion in an availableslot in the television program. By enforcing particular formattingrequirements for the video files that are submitted, the video can berapidly transcoded without the need to interpret the received data or tomodify the transcoder. Moreover, time slots within a television programcan be predefined for subsequent insertion of crowd-sourced content.

FIG. 2 shows an example system 200 that includes an implementation of aCCDS 202. The system 200 can include a collection of servers connectedto one or more communications network(s) 204, such as the Internet,cellular networks, satellite networks, cable networks, optical networks,and/or combinations thereof. In some implementations, the CCDS 202includes a plurality of servers, which can be implemented on any numberof computers. The CCDS 202 can include a web hosting server 206, a Flashserver 208, a web content server 210, a web auction server 212, atranscoding server 214, a television content server 216, and anadministrator server 218. The servers in the CCDS 202 can communicatewith one another through one or more networks (e.g., a local areanetwork and/or a wide area network). In some implementations, the system200 can be implemented within an environment such as depicted in anddescribed with reference to FIG. 1 of U.S. patent application Ser. No.13/013,775. The system 200 can be used, for example, to perform theprocess depicted in and described with reference to FIGS. 2A and 2B ofU.S. patent application Ser. No. 13/013,775. The system 200 or the CCDS202 can further support a ticker service as described depicted in anddescribed with reference to FIGS. 5, 6A and 6B of U.S. patentapplication Ser. No. 13/013,775.

The CCDS 202 communicates with a television distribution system 220,which can include a network operations center for a television networkand/or an uplink facility from which a television network feed isdistributed to carriers 228 that provide television services. Thetelevision distribution system 220 generally includes a program server222 for scheduling programs on the network; a traffic server 224 thatkeeps track of insertion points for insertion of prerecordedcommercials, promotional spots, and other announcements within eachscheduled television program; and a broadcast server 226 that generatesa linear programming feed for transmission to the carriers 228.

A user having a mobile device 230 (e.g., smart phone, tablet, etc.)capable of capturing SD or HD video or a computing device 232 having avideo camera 234 (e.g., built-in or aftermarket peripheral cameraattached via wired or wireless connection) can connect to thecommunications network(s) 204 and interface with the CCDS 202 (e.g.,through the web hosting server 206). The web hosting server 206 canprovide one or more web pages through which users can access servicesprovided by the CCDS 202. For example, the web hosting server 206 canhost a registration web page that allows users to register with the CCDS202 and a HD recorder web page that provides users with access to a thinclient application (or web application) that supports video capture (asdiscussed below in connection with FIGS. 3-15). In addition, the webhosting server 206 can allow fat client applications to be downloaded toand installed on the mobile device 230 or computing device 232. Ingeneral, a thin client or web application can provide a frictionlessuser experience because no installation of software is necessary tocapture and submit broadcast quality video, provided that the user hasbasic hardware (i.e., a computing device and a camera either built into,or attached to the computing device) necessary to perform audio andvideo capture. An installed application may be necessary or desired insome cases, e.g., where the mobile device 230 or computing device 232lacks support for a scripting language used to implement the thin clientfunctionality or when capture is to be performed offline. Nonetheless,such an installed application can perform the same operations andprovide the same functionality as the thin client application. In somecases, web hosting server 206 can provide video capture functionalityfor a third party web site (e.g., a third party web site that links tothe web hosting server 206 for use in capturing video for a televisionnetwork associated with the third party web site).

In some embodiments, when a user accesses the video capturefunctionality of the CCDS 202 (e.g., through a thin client applicationhosted on the web hosting server 206), the video capture interface canbe provided, at least in part, using the Flash® server 208. Inparticular, the Flash® server 208 can serve a Flash®-based interface tothe mobile device 230 or computing device 232 for use in capturingvideo. For example, the Flash® server 208 can provide scripts that allowthe user to define settings through the Flash®-based interface and thatreceive video data through an application programming interface (API) onthe mobile device 230 or computing device 232 for transmission to theCCDS 202.

Video data can be transmitted from the mobile device 230 or computingdevice 232 to the web content server 210. Video data that is capturedusing the Flash® server 208 can be transmitted (e.g., in FLV format) asthe video data is captured, although there may be some buffering of datato ensure compliance with video quality constraints, as discussedfurther in this specification. Video data can also be stored on thedevice 230 or 232 (e.g., using a specialized or third-party applicationinstalled on the device) and uploaded after the video file is complete.For example, the video data may be captured in H.264 or MP4 format,stored locally on a mobile device 230 or computing device 232, anduploaded to the web content server 210 through a thin client applicationor installed application on the mobile device 230 or computing device232.

Video data received at the web content server 210 can be stored in itsnative format (e.g., FLV, H.264, MP4, etc.) on the web content server210 or a database associated with the web content server. The storedvideo data can be automatically transcoded by the transcoding server 214into one or more alternative formats. The transcoding can be dependentupon user credentials (e.g., whether the user has registered to uploadvideo for web distribution and/or for television distribution, whetherthe user has been approved for uploading certain types of content,whether the user has been barred from certain types of submissions forprior submissions of inappropriate content, etc.) and can be based onthe type of submission. For example, a submission in response to arequest for videos on a certain subject and/or a submission intended forinclusion in a certain program can be submitted through a particular webpage, which may result in the video data being automatically transcodedinto one or more specific formats (e.g., a television format and a webformat). Transcoding can also include adding source indicia (e.g., in alower right hand corner to show the television channel on which thevideo is broadcast) or other additional information (e.g., a ticker orother information bar at the bottom of the video display). Thetranscoded video data can be stored (possibly along with a retainedversion of the native video data) on the web content server 210, thetelevision content server 214, or another database associated with theCCDS 202. The video data can be retrieved for viewing through thenetwork 204 and/or for distribution via television or on a web page. Insome cases, videos can be distributed according to an auction processusing the auction server 212, or using other consideration (e.g.,virtual credits), as described in pending U.S. patent application Ser.No. 13/013,775 (e.g., with reference to FIG. 4), the content of which isincorporated in this specification by reference.

Video content stored on the web content server 210, the televisioncontent server 216, or another database can be reviewed using anadministrator server 218. The video content can be reviewed forinappropriate content and/or for evaluation (e.g., for inclusion in aparticular segment of linear programming). In some implementations, thereview can be at least partially automated using an automated reviewserver 236, which can be included as part of the CCDS 202 or hosted on athird party server. The automated review server 236, for example, canscan the video frames and accompanying audio data to compare the videoand audio against databases of pornographic material, profanity, orother inappropriate material to identify similarities. Frames withcontent identified as questionable can be flagged for further manualreview or, in some cases, can be automatically disqualified fordistribution. The video content can also be organized for review usingthe administration server 218 according to the intended type ofdistribution (e.g., web or television) and program (e.g., such that anadministrator can review only videos submitted for inclusion in aparticular program). Manual review can be conducted by retrieving thevideos using the administrator server 218 through a thin clientapplication or an installed application local to the CCDS 202 or using acomputing device 238 that accesses the administrator server 218 acrossthe network 204. The administration server 218 can also be used toselect videos for inclusion in linear programming and to assign aparticular segment in which a video is included in linear programming.For example, the administration server 218 can access the televisiondistribution system 220 to assign a video to an available time slot orsegment in a linear programming sequence and/or to associate apreviously assigned content name included in the linear programmingsequence (e.g., a content name used as a placeholder for subsequentlygenerated video) to a video submitted through the CCDS 202.

The television distribution system 220 can include a network operationscenter for a television network and/or an uplink facility as describedin the '775 application. Generally, the program server 222 maintains adatabase that specifies the program, the episode, the date oftransmission, and start and stop times of each. Even when a program is“live,” it is accounted for in the programming grid utilizing theprogramming system. The program server 222 also typically includesadditional information on each program, such as its title, describingthe program so that it can be published in program guides, etc. Forexample, a network can use the program server 222, located within anetwork operations center, for scheduling programs on that network.Networks that sell advertising will also typically operate or make useof a traffic server 224 that is part of a network operations center. Thetraffic server keeps track of time slots, or so-called “insertionpoints,” within each scheduled TV program, that have been set aside forinsertion of a prerecorded commercials, promotional spots, and otherannouncements. The traffic server 224 stores information about each timeslot in one or more databases on one or more servers. The broadcastserver 226 is used in connection with creating or generating a linearprogramming feed or television signal that will be transmitted to thetelevision carriers 228. The broadcast server 226 assembles a programand any insertions into a continuous linear signal according to aschedule stored by the program server 222 and the insertion pointsspecified in the traffic server 224. Video content from the CCDS 202 canbe retrieved by the television distribution system 220 using, e.g., afile transfer protocol according to data provided when the administratorserver 218 is used to assign a particular video to a specific time slot.

The programming of a television network—the network's signal or feed—istypically distributed to viewers via one or more local broadcasttelevision stations for local broadcast and/or one or more carriers fortransmission on other mediums, such as cable TV systems, wired orwireless high-speed broadband networks, mobile data networks, satellitetelevision systems, for substantially simultaneous viewing by multipleusers.

A TV program to which a network has distribution rights could also bedelivered “on demand,” meaning at the request of a viewer, in which caseprogram transmission to that user begins at the request of a user andcontinues according to a predefined timeline. Such on-demand programsgenerally do not, but could, include predefined time slots within thetimeline of the program for advertising, promotional announcements, andother uses. However, transmission of such on-demand programming usuallyoriginates from the carrier, such as at the head end of a cable network,or from a server that streams the video over the Internet to the userrequesting it.

Typically, a network's signal or feed is transmitted by, or on behalf ofthe network, distributed simultaneously to one or more TV carriersacross some or all of a country or continent using a satellitetransmission system. However, other transmission systems, orcombinations of systems, can be used. A television network may own andoperate its own uplink facility, or it may choose to contract with oneor more third party uplink facilities to transmit its signal up to asatellite 240 for distribution to one or more television carriers 228.These television carriers 228 receive the satellite signal and transmitit on their systems to subscribers, who are represented by home 242, butcan include any type of residence, as well as bars, restaurants,theatres and other commercial establishments. Each subscriber has, inthis example, a set top box or some other gateway or device thatreceives and decodes the signal so that it can be played on a televisionor monitor 244. Representative examples of television carriers 228include a television service offered over a wired, terrestrial system,e.g., a cable television system or a cable-like television serviceprovided over a telecommunication network system, such as the VerizonFiOS® or AT&T U-VERSE® services, and a satellite television system, suchas DirectTV. Other types of distribution systems could be used fortransmitting a network's feed to subscribers, including IP televisionservices, which use the Internet protocols and packet-switchednetworking architectures to carry the signal to subscribers. Thetelevision signal or feed generated by the broadcast server 226, is, forexample, transmitted to an IP television service provider through asatellite uplink or, alternately, a private network or other connection.

Referring now to FIG. 3, the CCDS can be accessed using a softwareinterface that is executed on a user computing device. In someimplementations, the software can provide a web-based recording,editing, and uploading user interface 300. For example, the userinterface 300 can be implemented as the user interface depicted in anddescribed with reference to FIG. 3 of U.S. patent application Ser. No.13/013,775. The interface 300 can serve as a user-facing front-end ofthe CCDS, enabling a user to record and upload digital content (e.g.,digital video) for distribution. In some implementations, the interface300 enables a registered user to record an SD or HD video that is sentto the CCDS for storage or distribution to appropriate locations. Forexample, the user can use a computer with a built-in digital videocamera, a peripheral digital video camera attached to a computer, and/ora mobile device with a built-in camera and a pre-defined application togenerate digital video content that is streamed to the CCDSsubstantially in real time as the content is created. Thus, the camerais communicably coupled to the computer or other user device. In someimplementations, the interface 300 enables the user to upload apre-recorded video file that is stored in computer-readable memory tothe CCDS.

In operation, the CCDS can perform as an automated system that considersone or more of the following factors: (1) an individual user'scredentials and affiliations; (2) an individual user's recording andup-loading device; and/or (3) an individual user's desired destinationfor the media file. Considering these factors, the CCDS canautomatically determine both the source and the destination(s) of auser-generated video file, and then determine and transcode the fileinto the appropriate digital format(s) based upon the finaldestination(s) and viewing purpose (e.g., television or Internet) of thevideo file. User credentials and/or attributes associated with the videocontent submitted by a user can be used to determine whichadministrator(s) should review the video (e.g., so a particularadministrator only has to review videos submitted for his or herassigned programming) and to determine whether the individual ispermitted to submit videos for certain types of distribution. Forexample, user credentials can be updated over time to increment a userrating based on quality content or other factors and/or to decrement theuser rating based on submission of inappropriate content.

In some implementations, as discussed in further detail herein, theinterface 300 provides a recorder that utilizes Adobe® Flash® recordingtechnology to reduce the behavioral friction associated with creatingand publishing video content using the Internet. This option not onlyprevents the need for a user to download any software to record content,but it also makes access to the recording interface ubiquitous.Regardless of device or operating system, users from virtually anycommercially viable system are able to record and upload video that canbe transcoded into broadcast quality video files and/or into video filesappropriate for Internet distribution. The CCDS can distribute theappropriately transcoded video files (with or without manual productionor administrative review) to either television broadcast outlets orInternet distribution outlets using the interface 300. This featureeliminates the need of a professional production team to transcodedisparate formats of user-generated video files before the team cancompile and review the files for inclusion in live or pre-recordedlinear television or other programming. This aspect not only makeproduction less expensive for television or movie production teams, itmakes is the process simpler, and therefore more likely that aproduction team will want to include crowd-sourced content in theirprogramming (e.g., television or movie programming). The broadcastquality requirements may vary, and may be easily adjusted within theCCDS using predetermined automated transcoding workflows, depending on aparticular broadcaster or satellite uplink provider, distributionoutlet, or on a format required to be able to perform the broadcasting.For example, broadcast quality requirements for a standard definitionbroadcast may include a particular bit rate, type of codec, minimumpixel resolution, video frame rate, audio quality, and the like. Ingeneral, the quality level of the uploaded file may be required to besufficient to transcode a received Flash® video file or a file inanother format into a video file format that complies with broadcastrequirements. In other instances when a video file is to be distributedonly via the Internet, H.264 format may be sufficient. The followingparameters provide one example of the requirements for an SD broadcast:

Omneon Codec: ML@MP CBR

Bit rate: 15 Mb

GOP: IBBPBBPBBPBB

Resolution: 720×480

Frame rate: 29.97 frames-per-second (fps)

Video extension: .mpg

Enable Omneon User Data Creation: true

Preserve source timecode in file headers: true

Save as start timecode in file header: true

Save as first frame in file header: true

Output file type: self-contained

Output file extension: mxf

AIFF audio

-   -   4 channels/4 channels per file    -   24 bit

Video

-   -   24 bits per pixel

Components of the interface 300 can include controls that enable theuser to make various selections, such as a video source section control302, audio source selection control 304, and an Internet connectionspeed selection control 306. For example, referring to FIG. 4, videosource selection control 302 enables the user to select video recordingsource. Consequently, if a peripheral camera is connected to a devicehaving a built-in camera, the user can have the option of selectingeither the built-in camera or the connected peripheral camera.Additionally, referring to FIG. 5, audio source selection control 304enables the user to select an audio recording source. Consequently, if aperipheral camera having a microphone or a peripheral microphone isconnected, the user can have the option of selecting either the built-inmicrophone or a connected peripheral microphone. Also, referring to FIG.6, Internet connection speed control 306 enables the user to select thespeed of their Internet connection in order to adjust for uploadingdigital content files to the CCDS.

Returning to FIG. 3, a recording duration settings control 308 can beprovided. Referring to FIG. 7, recording duration settings control 308enables the user to pre-select duration of a video to be recorded forsubmission. For example, options presented for user selection can be15-second “fame spots,” 30-second “peoplemercials,” or videos of anylonger or lesser duration for video blogs or for inclusion in certainlinear television programs. In some implementations, multiple lengthscan be added to accommodate various programming formats, and/or videolengths can also be altered by the user. In some implementations, theduration can be specified based on a request for submission ofcrowd-sourced content. For example, a request can be broadcast at thebeginning of a television program or otherwise distributed (e.g., byemail or through a web page) to submit videos for potential inclusion ina television program (e.g., later in the same television programbroadcast) or other media production. The request can instruct users tovisit a particular web page that includes a thin client recordingapplication through which the users can record and submit video and/orother content, and the thin client recording application on that webpage can enforce a particular duration to ensure that editing of thevideo length is not required. Referring to FIG. 8, in someimplementations, when the user selects a 15-second option, the user canbe presented with a display component having a counter indicating howmuch time is left until the completion of the recording. Accordingly,the user can see a timer 310 of 15-seconds for a “FameSpot.” Referringto FIG. 9, the timer 310 can have 30-seconds when the user selects torecord a 30-second “peoplemercial.” Referring to FIG. 10, as the userapproaches the end of the 15 second or 30-second recording timeallocation, the timer 310 can approach 00:00 to let the user know tocomplete the final portion of the recording.

Returning to FIG. 3, other selection controls can be a video typeselection control 312 and video recording filters controls 314. In someimplementations, referring to FIG. 11, the video type selection control312 can offer example options: SD and HD. However, it is envisioned thatadditional or alternative video type options can be presented. Referringto FIG. 12, if the user selects the HD option, the system can present aquery 316 asking the user to confirm the fact that there is an HD cameraavailable for the recording. Additionally, referring to FIG. 13, thevideo recording filters controls 314 can offer the user the capabilityto adjust brightness, contrast, saturation, and/or sharpness of thepicture generated by their built-in or connected peripheral camera.

Returning to FIG. 3, another control of the interface 300 can be videorecording controls 318. Referring to FIG. 14, the recording controls canoperate in an intuitive manner for most users. For example, a far-leftbutton with a red dot in the middle can be provided as a record button.Also, a middle button with a square can be a stop button, and a buttonall the way to the right with a triangle can be a play button. However,referring to FIG. 15, a recording countdown display 320 can also beprovided. For example, once a user “clicks” the record button, the usercan be given a count-down from 3-2-1 (e.g., in red numbers) to let theuser know when the recording will begin. As already detailed above,while the recording is taking place, a separate counter (e.g., forfamespots, peoplemercials or social clips) can count down from theappropriate starting point (e.g., 15 seconds, 30 seconds, or otherlengths respectively).

With regard to recording, and as introduced above, implementations ofthe present invention enable web-based recording to generate videocontent using a thin client Flash® recorder executed on a computingdevice that communicates with one or more back-end servers. In someimplementations, the thin client Flash® recorder is downloaded to theclient computing device as part of a web page of a website that ishosted using the one or more back-end servers. Scripts within the webpage provide the functionality of implementing the various recordingcontrols discussed above with reference to FIGS. 3-15.

Video data can be generated using a local video camera through anassociated API. The video data can include both image data and audiodata. The client-side recorder ensures that the video data is ofsufficient quality for broadcast purposes, which can require very highquality, or for web video blogs, for example, which can be achievedusing a lower quality level. In some implementations, the client-siderecorder can notify the user whether the equipment (e.g., camera) orrecording settings are adequate for broadcast video. In someimplementations, the client-based recorder ensures that sufficient videodata is encoded within the subsequent video file.

Using the system of FIGS. 1 and 2, during recording, and as the videocamera generates video data, the video data can be cached andtransmitted to the one or more back-end servers. The web-based recordercaptures and caches sufficient video data to retain broadcast qualityrequirements and transmits the video data to the one or more back-endservers in quasi-real time. More specifically, as video data isgenerated, the video data is cached and a predetermined amount of videodata is intermittently transmitted from the client computing device tothe one or more back-end servers. The pre-determined amount of videodata that is transmitted can be determined based on the availabletransmission bandwidth instead of, for example, adapting image qualityto meet limited bandwidth availability. Upon receiving the video data atthe one or more back-end servers, a corresponding video file isgenerated and is stored. The video file can be in the FLV format and caninclude any video data necessary to meet quality requirements. Bycaching and streaming the video data from the client computing device tothe one or more back-end servers, the compression and transmission of acomplete video file from the client computing device to the back-endservers is avoided. In this manner, data loss that can occur throughconventional compression technologies is avoided.

As discussed herein, when using web-based recording, the video file canbe sent from a computing device in the FLV format. In someimplementations, a pre-recorded video file can alternatively be uploadedto the one or more back-end servers (e.g., from a computing device).Such pre-recorded video files can be provided in the FLV format, the MOVformat (e.g., from a computing device that does not support Flash®), oranother format. The video file can be transcoded to a format that isappropriate for a designated downstream use. In some implementations,the video file can be provided to a server, which transcodes the videofile to a desired format. Once stored to the server, the serverimmediately transcodes the video file using ffmpeg modifications andlibrary additions to ensure quality retention and synchronization toprovide a video file (e.g., in MP4 format) that meets qualityspecifications. By way of non-limiting example, upon completion of aweb-based recording, the resultant video file in FLV format can beprovided to a file server that immediately transcodes (e.g., usingFlipFactory™ video transcoding software) the video file into one or moreother formats (e.g., MOV and MP4; from MP4 to MXF, and/or directly fromFLV to MXF). Generally, MOV, MP4, and H.264 are common Internet formats,while MXF or MV4 can be used for broadcast television. In someimplementations, video file format transcoding can be based on the userprofile. For example, if the user that created or submitted the videofile is registered for video blogs, for broadcast television, or both,the underlying video file can be transcoded into the appropriate formatsand delivered to both destinations.

An image file is generated and can be provided in JPEG format or anotherappropriate image file format. The image file is used as a thumbnailimage representing the video file. A frame from the beginning of thevideo can be selected using the ffmpeg extension for the PHP scriptinglanguage. GIF draw (GD) can be used to create the image from theselected frame. Another script can be executed to determine whether thevideo is oriented correctly. If it is determined that the video is notcorrectly oriented, the video file can be processed to correctly orientthe video.

Referring now to FIG. 16, an example web-based method of recording andproviding broadcast quality digital video content (e.g., in the form of“famespots,” “peoplemercials,” or social clips) from a client computerwill be discussed. A user registers at a website hosting the CCDS clientapplication (400). The user can open/launch a recording and uploadinguser interface (RUUI) (402), as described above with reference to FIGS.3-15. Using the interface, the user can make various selections (404).As discussed above, user selections can include one or more of camerasource, audio source, Internet connection, duration of recording (blog,15-second “famespot,” 30-second “peoplemercial,” social spot, videoblog, etc.), video type (e.g., SD, HD, etc.), and video filteradjustments. The user can activate video recording buttons of theinterface, to initiate video recording and creation of a correspondingdigital video file (406).

The digital video can be recorded in Flash® format (i.e., FLV format)using a Flash® server (e.g., server 202 of FIG. 2) (408). Other formats(e.g., capable of providing streaming video data) other than the FLVformat (e.g., silverlight, SVG, etc.) can be implemented. In particular,and in the case of recording through a website, the website receivesvideo and audio from the selected input devices through a communicationinterface on the user computer, and scripts provided in the retrievedweb page encode the video in FLV format in accordance with qualityparameters. Example quality parameters can include frame rate,resolution, aspect ratio, stereo at 48 kHz sampling, audio and video bitrate, which are deemed to be of sufficient quality for broadcastpurposes. By way of non-limiting example, the flash recorder of theinterface can record in HD at a frame rate of 30 fps (or, in some cases,29.97 fps) and at a bit-rate of 15 mega-bits per second, which is ofhigher quality than conventional Flash® recording. That is, the recorderprovided by the interface records in accordance with parameters thatenable the FLV file to be transcoded into a video file that meetsspecific quality parameters for a selected type of distributiondestination. The scripts are executed to cache and transmit the FLVvideo. For example, the video data can be placed in a cache, orotherwise buffered, and can be transmitted from the cache based onavailable bandwidth. As another example, the video data can be cachedand transmitted only when the available bandwidth is insufficient tokeep up with a required bit rate).

The video file can be transcoded (410) and submitted to an automatedscreening process (412). The video file can be transcoded into multiplefile formats in parallel or nearly in parallel. For example, the videofile can be transcoded into one or more Internet formats (e.g., MOV,MP4) and into one or more television formats (e.g., MXF). Generally,although not necessarily, the video file can be submitted to theautomated screening process in a transcoded format, rather than in,e.g., the FLV format. For example, the video file can be processed andcan be transcoded to another video format (e.g., MOV, MP4) prior tosubmission to the automated screening process. As discussed herein, theautomated screening process can pre-screen the video file and can flagframes within the video that may require additional scrutiny. Thepre-screened video file is made available for manual review byadministrators (414). As discussed in further detail herein, anadministrator can employ an administrative user interface (see FIG. 17)to access the pre-screened video files on web hosting server 206 (seeFIG. 2) for manual review and approval (416). Approved videos can entera selection process (418) for integration into a linear programmingschedule. Thus, videos can be reviewed (automated and/or manual review)in one or more formats and, if selected for integration into a linearprogramming schedule, the corresponding video in an appropriatetelevision format can be sent, marked for retrieval, or otherwiseidentified for inclusion in the linear programming schedule.Accordingly, by transcoding video in parallel or near parallel (e.g.,during an at least partially overlapping time period, or transcodinginto an appropriate television format while the video is undergoingautomated and/or manual review), the video in a format appropriate fortelevision can be ready for integration into the linear programmingschedule immediately or nearly immediately after selection. In someimplementations, the selection process can further include an auctionprocess. If, as determined during the selection process, the video is tobe broadcast (e.g., on a television channel), a time slot is assigned(420), and the video is broadcast at the assigned time slot. In someimplementations, the selection process can include an administratorselecting and scheduling video broadcasts.

In some implementations, an administrator can select the video andassign the video to a particular slot in a linear programming scheduleusing, for example, the review and authorization interface 134 ofFIG. 1. For example, the administrator can provide the video file ascorresponding to a previously provided program name that is assigned toa specific time slot. As another example, the administrator can inform atraffic server of the video file name and assigned time and provide thevideo file to a traffic server (e.g., the traffic server 224 of FIG. 2).To this end, the interface can be used to display the linear programmingschedule to the administrator, and the administrator can manuallyinterface with the traffic and program servers to insert programs intothe linear programming schedule. In some implementations, theadministration process can automatically interface with the traffic andprogram servers to dynamically insert programs into the linearprogramming schedule. For example, the video file can be stored ontraffic server 224 (see FIG. 2) for integration with linear programmingsent to broadcast server 226 (see FIG. 2) prior to being sent out over acable and/or satellite distribution network.

Referring now to FIGS. 17A-17C, the administrator interface will bediscussed in further detail. The administrator interface enables anadministrator to participate in a review process to review, authorize,or decline certain video files. As shown in FIG. 17A, the administratorinterface can enable an administrator to view and select one or morethumbnails corresponding to different videos that are available forreview. The videos can be selected based on a filter that corresponds tothe content and the particular administrator's review responsibility, asdiscussed above. The administrator interface can be used to select whichvideos to manually review (e.g., sequentially, in any selected order, orusing filters as discussed above, for identifying particular videos forinclusion in a program).

In some implementations, the review process can include sending a videofile to a third-party service that processes the video file and thatflags questionable content. For example, the third-party service canexecute software that automatically compares one or more frames of thevideo to a database of suspect or questionable images. If a frame of thevideo sufficiently matches an image in the database, metadata can begenerated that annotates the video file to flag the suspect frame and anannotated video file can be provided to the administrator for manualreview. In some implementations, the third-party service provides a listof frame identifiers (IDs) that correspond to flagged frames. In someimplementations, the third-party service provider can generate andprovide a thumbnail image of each flagged frame. The frame ID and/orcorresponding thumbnail image can be presented on the administratorinterface. In some implementations, by selecting one of the thumbnails,the video can be presented on the administrator interface as shown inFIG. 17B with a representation of a playback line 450 that correspondsto the length of the video can be displayed and can include markers 452indicating the location within the video of one or more frames flaggedas having suspect or questionable content.

As shown in FIG. 17C, the administrator can designate selected videos tobe sent for broadcast, for editing (e.g., using Avid® video editingsoftware or Final Cut Pro® video editing software), or for furtherreview. The administrator can, for example, select from a drop down menuof particular destinations (e.g., ftp servers associated with aparticular destination or additional processing workflow) and/or defineadditional destinations for the selected videos. In someimplementations, as discussed above, the administrator interfacedisplays a linear programming schedule and can highlight open slots, orslots that have been assigned to a placeholder name but that do not havea video assigned thereto. Using the administrator interface, theadministrator can manually assign a selected video file with a specifictime slot.

Referring now to FIG. 18, a method of recording and submitting broadcastquality video files from a smart phone or mobile device can begin with auser downloading and installing a mobile application (e.g., on acomputing device) (500). The mobile application can be opened and theuser can log into the mobile application using pre-defined credentials.A mobile recording user interface (MRUI) is launched (502) by, forexample, selecting a video capture button on a bottom-right-hand cornerof the user interface (see FIG. 19). A “Record New Video” option (seeFIG. 19) can be selected (504), and the user can be presented withrecording options. Example recording options can include recording a 15second video file known, for example, as a “famespot” or a 30 secondvideo file, for example, known as a “peoplemercial” (see FIG. 20). Theduration of the video file can be used to determine its positioning inlinear TV programming. Upon completing these selections, a new recordinginterface can open that can be employed to record a video (506). Inparticular, the user can initiate recording of a video by pressing, forexample, a red record button, and a countdown timer can be displayed,for example, in an upper-right hand corner that counts down remainingtime (see FIG. 21).

The recorded video can be played back, and the “retake” or “use” thevideo (see FIG. 22) can be selected (508). If the user selects to usethe video, then a new option can appear to allow the user to upload thevideo (510) to the CCDS (see FIG. 23). When upload is selected, a videoname can be input (see FIG. 24) (512). Upon selecting to submit thevideo (see FIG. 25), the video file can be transmitted (514) from themobile device to a web content server 210 (see FIG. 2). At least somemobile devices do not support FLV format, so the video file can bestored on the mobile device in a format supported by the device (e.g.,MOV format) and transmitted to the web content server in that sameformat. Depending upon the final destination of the video (e.g.,television broadcast, Internet broadcast), the video file can beimmediately transcoded into one or more other formats another format(e.g., MV4 and MXF video files) on the web content server 210 (516). Itis envisioned that additional or alternative formats will be readilyapparent to one skilled in the art. Once the files have been saved onthe web content server 210, the user can be notified (518) that theupload was successful (see FIG. 26). In some implementations,transcoding can be performed or at least initiated simultaneously with,or even before, notifying the user of the successful upload. Thereafter,the video can be submitted for automated screening (520), manual review(522), authorization (524), selection (526), and time slot assignment(528), as similarly discussed above with reference to FIG. 16.

Referring now to FIG. 27, a method of uploading pre-recorded broadcastquality digital video content (e.g., “famespots,” “peoplemercials,”)from a computing device can begin with a user registering at a websitehosting the CCDS (600). A recording and uploading user interface (RUUI)can be opened and launched (602), as similarly described above withreference to FIGS. 3-15. A video file can be selected for upload (604)through user interaction with a “Browse” button 322 (see FIG. 3). Inresponse, the UI software can automatically open a window to enable theuser to find a video file on the local computing device (see FIG. 28).The user can select a video file for distribution and broadcast (604).The video file is uploaded (606) and the CCDS can detect the video fileformat. In some implementations, and depending on the destination of thevideo file (e.g., for television broadcast), the transcoding server 214can transcode the video file to MXF television broadcasting format andcan save the transcoded video file to television content server 216. Thevideo can be submitted for automated screening (608), manual review(610), authorization (612), selection (614), and time slot assignment(616), as similarly described above with reference to FIG. 16.

Referring now to FIG. 29, a method of uploading pre-recorded broadcastquality digital video (e.g., “famespots,” “peoplemercials”) from amobile computing device can begin with a user installing a mobileapplication (700). The mobile application can be launched and a mobilerecording user interface (MRUI) can be opened (702) by, for example,selecting a video capture button on a bottom-right-hand corner of themobile application (see FIG. 30). A plurality of digital videos can beaccessed for selection of a digital video (704). For example, a “Choosefrom Library” option can be used to access a library of stored digitalvideo files (see FIG. 31). A digital video can be selected (706), andthe video file can be imported to the mobile application. In someimplementations, the user can play the video to confirm that it is thedesired video file, and cancel and select another digital video file, or“Choose” to upload the file (see FIG. 32). In response to selecting aparticular digital video file for upload, the selected digital videofile can be compressed and transmitted (708) to a web content server 210(see FIG. 33) so that the digital video file can be stored on webcontent server 210. Once the file compression is complete, the user canconfirm upload to the CCDS (710) (see FIG. 34), and assign a name to thevideo file (712) if the upload option was selected (see FIG. 35). Uponnaming and submitting the file, web content server 204 can immediatelyand automatically transcode (714) the video file into the appropriatefile format(s) and store the newly transcoded video file on web contentserver 210 and/or the television content server 216. Once the files havebeen transcoded and saved on web content server 210, the user can benotified that the video file has been uploaded successfully (see FIG.36). Thereafter, the video can be submitted for automated screening(716), manual review (718), authorization (720), selection (722), andtime slot assignment (724), as similarly described above with referenceto FIG. 16.

No particular computer architecture is intended to be implied by thisexample. The example is intended to be representative generally ofcomputing systems suitable for being programmed to perform theseprocesses, and not limiting. Execution of a process need not be limitedto a single computing system, but could be distributed among more thanone computing system. Programs running on a computing system or onmultiple computing systems execute parts of the process described in theflow diagrams of FIGS. 2A, 2B, 3, 4 and 5. Multiple instances of aprocess may execute on the same or on multiple different computingsystems. Instances of each of the servers 22, 24, 26 and 28 could run onthe same computer, or on different virtual machines on the samecomputer.

A number of implementations have been described. Nevertheless, it willbe understood that various modifications may be made without departingfrom the spirit and scope of the disclosure. For example, various formsof the flows shown above may be used, with steps re-ordered, added, orremoved. Accordingly, other implementations are within the scope of thefollowing claims.

Implementations of the present disclosure and all of the functionaloperations provided herein can be realized in digital electroniccircuitry, or in computer software, firmware, or hardware, including thestructures disclosed in this specification and their structuralequivalents, or in combinations of one or more of them. Implementationsof the invention can be realized as one or more computer programproducts, i.e., one or more modules of computer program instructionsencoded on a computer readable medium for execution by, or to controlthe operation of, data processing apparatus. The computer readablemedium can be a machine-readable storage device, a machine-readablestorage substrate, a memory device, a composition of matter affecting amachine-readable propagated signal, or a combination of one or more ofthem. The term “data processing apparatus” encompasses all apparatus,devices, and machines for processing data, including by way of example aprogrammable processor, a computer, or multiple processors or computers.The apparatus can include, in addition to hardware, code that creates anexecution environment for the computer program in question, e.g., codethat constitutes processor firmware, a protocol stack, a databasemanagement system, an operating system, or a combination of one or moreof them.

A computer program (also known as a program, software, softwareapplication, script, or code) can be written in any form of programminglanguage, including compiled or interpreted languages, and it can bedeployed in any form, including as a stand-alone program or as a module,component, subroutine, or other unit suitable for use in a computingenvironment. A computer program does not necessarily correspond to afile in a file system. A program can be stored in a portion of a filethat holds other programs or data (e.g., one or more scripts stored in amarkup language document), in a single file dedicated to the program inquestion, or in multiple coordinated files (e.g., files that store oneor more modules, sub programs, or portions of code). A computer programcan be deployed to be executed on one computer or on multiple computersthat are located at one site or distributed across multiple sites andinterconnected by a communication network.

The processes and logic flows described in this disclose can beperformed by one or more programmable processors executing one or morecomputer programs to perform functions by operating on input data andgenerating output. The processes and logic flows can also be performedby, and apparatus can also be implemented as, special purpose logiccircuitry, e.g., an FPGA (field programmable gate array) or an ASIC(application specific integrated circuit).

Processors suitable for the execution of a computer program include, byway of example, both general and special purpose microprocessors, andany one or more processors of any kind of digital computer. Generally, aprocessor will receive instructions and data from a read only memory ora random access memory or both. The essential elements of a computer area processor for performing instructions and one or more memory devicesfor storing instructions and data. Generally, a computer will alsoinclude, or be operatively coupled to receive data from or transfer datato, or both, one or more mass storage devices for storing data, e.g.,magnetic, magneto optical disks, or optical disks. However, a computerneed not have such devices. Moreover, a computer can be embedded inanother device, e.g., a mobile telephone, a personal digital assistant(PDA), a mobile audio player, a Global Positioning System (GPS)receiver, to name just a few. Computer readable media suitable forstoring computer program instructions and data include all forms ofnon-volatile memory, media and memory devices, including by way ofexample semiconductor memory devices, e.g., EPROM, EEPROM, and flashmemory devices; magnetic disks, e.g., internal hard disks or removabledisks; magneto optical disks; and CD ROM and DVD-ROM disks. Theprocessor and the memory can be supplemented by, or incorporated in,special purpose logic circuitry.

To provide for interaction with a user, implementations of the inventioncan be implemented on a computer having a display device, e.g., a CRT(cathode ray tube) or LCD (liquid crystal display) monitor, fordisplaying information to the user and a keyboard and a pointing device,e.g., a mouse or a trackball, by which the user can provide input to thecomputer. Other kinds of devices can be used to provide for interactionwith a user as well; for example, feedback provided to the user can beany form of sensory feedback, e.g., visual feedback, auditory feedback,or tactile feedback; and input from the user can be received in anyform, including acoustic, speech, or tactile input.

Implementations of the present disclosure can be realized in a computingsystem that includes a back end component, e.g., as a data server, orthat includes a middleware component, e.g., an application server, orthat includes a front end component, e.g., a client computer having agraphical user interface or a Web browser through which a user caninteract with an implementation of the present disclosure, or anycombination of one or more such back end, middleware, or front endcomponents. The components of the system can be interconnected by anyform or medium of digital data communication, e.g., a communicationnetwork. Examples of communication networks include a local area network(“LAN”) and a wide area network (“WAN”), e.g., the Internet.

The computing system can include clients and servers. A client andserver are generally remote from each other and typically interactthrough a communication network. The relationship of client and serverarises by virtue of computer programs running on the respectivecomputers and having a client-server relationship to each other.

While this disclosure contains many specifics, these should not beconstrued as limitations on the scope of the disclosure or of what maybe claimed, but rather as descriptions of features specific toparticular implementations of the disclosure. Certain features that aredescribed in this disclosure in the context of separate implementationscan also be provided in combination in a single implementation.Conversely, various features that are described in the context of asingle implementation can also be provided in multiple implementationsseparately or in any suitable sub-combination. Moreover, althoughfeatures may be described above as acting in certain combinations andeven initially claimed as such, one or more features from a claimedcombination can in some cases be excised from the combination, and theclaimed combination may be directed to a sub-combination or variation ofa sub-combination.

Similarly, while operations are depicted in the drawings in a particularorder, this should not be understood as requiring that such operationsbe performed in the particular order shown or in sequential order, orthat all illustrated operations be performed, to achieve desirableresults. In certain circumstances, multitasking and parallel processingmay be advantageous. Moreover, the separation of various systemcomponents in the implementations described above should not beunderstood as requiring such separation in all implementations, and itshould be understood that the described program components and systemscan generally be integrated together in a single software product orpackaged into multiple software products.

Thus, particular implementations of the present disclosure have beendescribed. Other implementations are within the scope of the followingclaims. For example, the actions recited in the claims can be performedin a different order and still achieve desirable results. What isclaimed is:

1. A method performed by data processing apparatus, the methodcomprising: receiving video data from a client computing device, whereinthe video data is captured using a camera connected to the clientcomputing device in accordance with instructions executed on the clientcomputing device to provide the video data in accordance withpredetermined constraints; automatically transcoding the video data,using a server, into at least one different format based on at least oneof user credentials associated with a user of the client computingdevice or attributes associated with the video data, wherein at leastone format of the transcoded video data defines a video file in a formatappropriate for inclusion in a linear television programmingtransmission; and uploading the transcoded video data to a server fordistribution.
 2. The method of claim 1 wherein the instructions executedon the client computing device include scripts received by the clientcomputing device from a web application.
 3. The method of claim 1wherein the instructions executed on the client computing device areexecuted within at least one of a browser or a browser plugin on theclient computing device.
 4. The method of claim 1 wherein theinstructions executed on the client computing device are included in anapplication installed on the client computing device.
 5. The method ofclaim 1 wherein at least a portion of the video data is buffered on theclient computing device using scripts included in the instructionsexecuted on the client computing device based on bandwidth constraintsfor transmitting the video data from the client computing device.
 6. Themethod of claim 1 wherein the video data is transmitted by the clientcomputing device in FLV format.
 7. The method of claim 1 wherein thevideo data is transmitted by the client computing device in a nativemedia container format for the client computing device.
 8. The method ofclaim 1 wherein the predetermined constraints include a bit rate and animage resolution sufficient to enable transcoding of the video data intothe format appropriate for inclusion in the linear televisionprogramming transmission.
 9. The method of claim 1 wherein transcodingthe video data includes using a predetermined automated transcodingworkflow corresponding to the predetermined constraints to transcode thevideo data into the transcoded video data.
 10. The method of claim 1wherein transcoding the video data includes transcoding the video datainto a plurality of different video file formats.
 11. The method ofclaim 1 further comprising performing an automated review of at leastone of the video data or the transcoded video data to identifypotentially inappropriate content.
 12. The method of claim 11 furthercomprising: retrieving the transcoded video data for manual review; andpresenting a review interface adapted to: provide an indication of atleast one frame within the transcoded video file including contentidentified as potentially inappropriate content; and allow anadministrator to select the transcoded video file for manual review. 13.The method of claim 1 further comprising: retrieving the transcodedvideo data for manual review; presenting a review interface adapted toallow an administrator to select among a plurality of transcoded videofiles for manual review; receiving a selection of a particulartranscoded video file for review through the review interface;presenting video defined by the particular transcoded video file throughthe review interface in response to the selection; and receiving aselection of the particular transcoded video file for publicationthrough the review interface, wherein uploading the transcoded videodata to a server is performed in response to the selection of theparticular transcoded video file for publication.
 14. The method ofclaim 1 wherein the video data is received in response to a request tosubmit content for potential inclusion in a linear televisionprogramming transmission.
 15. The method of claim 1 whereinautomatically transcoding the video data includes transcoding the videodata into at least one format appropriate for Internet distribution, themethod further comprising storing the transcoded video data in the atleast one format appropriate for Internet distribution on a web serveradapted to allow retrieval through a web page.
 16. The method of claim15 further comprising distributing the transcoded video data to aplurality of social networking web sites.
 17. A computer storage mediumencoded with a computer program, the program comprising instructionsthat when executed by data processing apparatus cause the dataprocessing apparatus to perform operations comprising: displaying, on aclient computing device, a user interface adapted to allow a user toselectively record content including high definition video contentthrough a digital camera communicably coupled to the client computingdevice; receiving a user selection to record content; capturing highdefinition video data using the digital camera during a continuousrecording segment; formatting the high definition video data inaccordance with predetermined constraints; and transmitting at least aportion of the formatted high definition video data to a storage serverduring the continuous recording segment.
 18. The computer storage mediumof claim 15 wherein the operations are performed using scriptstransmitted to the client computing device in a web page and executed onthe client device using at least one of a web browser or a web browserplugin.
 19. The computer storage medium of claim 17 wherein thepredetermined constraints are adapted to enable a transcoding server toperform automated transcoding of the high definition video data into aplurality of video file formats.
 20. The computer storage medium ofclaim 17, the operations further comprising caching a portion of thehigh definition video data on the client computing device fortransmission in accordance with bandwidth limitations on transmittingthe formatted high definition video data.
 21. The computer storagemedium of claim 17, the operations further comprising associating one ormore attributes with the formatted high definition video data, the oneor more attributes associated with at least one of a request forsubmissions of content to be included in a television broadcast or auser credential.
 22. A computer storage medium encoded with a computerprogram, the program comprising instructions that when executed by dataprocessing apparatus cause the data processing apparatus to performoperations comprising: displaying, on a client computing device, a userinterface adapted to allow a user to selectively record contentincluding high definition video content through a digital cameracommunicably coupled to the client computing device; receiving a userselection to record content; capturing high definition video data usingthe digital camera during a continuous recording segment; formatting thehigh definition video data in accordance with predetermined constraints;establishing a connection with a content submission server in responseto a user selection to upload the high definition video data; andtransmitting the formatted high definition video data to a storageserver using the connection in response to the user selection, whereinthe predetermined constraints are adapted to facilitate transcoding ofthe formatted high definition video data into a format appropriate forinclusion in a linear television programming transmission.
 23. Thecomputer storage medium of claim 22 wherein formatting the highdefinition video data includes formatting the high definition video datain a native media container format for the client computing device. 24.The computer storage medium of claim 22 wherein the operations areperformed using instructions transmitted to the client computing devicedownloaded from a web server and installed on the client device, andcapturing high definition video data using the digital camera includesinterfacing with native device recording capabilities.
 25. The computerstorage medium of claim 22, the operations further comprisingassociating one or more attributes with the formatted high definitionvideo data, the one or more attributes associated with at least one of arequest for submissions of content to be included in a televisionbroadcast or a user credential.
 26. A system comprising: a user device;and one or more servers operable to interact with the user device andto: receive video data in a predetermined format from the user device;transcode the video data into one or more video formats that differ fromthe predetermined format using an automated transcoding workflowcorresponding to the predetermined format; store the transcoded videodata; and distribute the transcoded video data for inclusion in atelevision transmission
 27. The system of claim 26 wherein the one ormore servers are further adapted to provide instructions for executionon the user device in a web page, wherein the instructions are adaptedto cause the user device to capture the video data using a cameraconnected to the user device and to transmit at least a portion of thevideo data to a web server of the one or more servers as the video datais captured.
 28. The system of claim 26 wherein the one or more serversare further adapted to transcode the video data into a formatappropriate for inclusion in a linear television programmingtransmission.
 29. The system of claim 26 wherein the one or more serversare further adapted to: retrieve the transcoded video data for manualreview; and present a review interface adapted to: provide an indicationof at least one frame within the transcoded video file including contentidentified as potentially inappropriate content; and allow anadministrator to select the transcoded video file for manual review. 30.The system of claim 26 wherein the one or more servers are furtheradapted to: retrieve the transcoded video data for manual review;present a review interface adapted to allow an administrator to selectamong a plurality of transcoded video files for manual review; receive aselection of a particular transcoded video file for review through thereview interface; present video defined by the particular transcodedvideo file through the review interface in response to the selection;and receive a selection of the particular transcoded video file forinclusion in the television broadcast, wherein the transcoded video datais distributed for inclusion in a television broadcast in response tothe selection of the particular transcoded video file for inclusion inthe television broadcast.